Aerodynamic surgical light and boom systems

ABSTRACT

Disclosure herein are aerodynamic surgical lights and methods of manufacturing and use thereof. The aerodynamic surgical lights may include a light head made of one or more substantially tubular light housings. The substantially tubular light housings contain and protect a plurality of LED lights and their respective reflectors that aim a light beam toward the lower side of the substantially tubular light housings. The substantially tubular light housings are vertically elongate. The vertically elongated substantially tubular light housings include upper sections that are aerodynamically curved or pointed to streamline airflow past the light housings. The upper sections of the substantially tubular light housings are made of molded plastic resin reinforced with carbon fibers or glass fibers and the lower sections of the substantially tubular light housings are made of a clear moldable plastic.

PRIORITY

This application is a continuation of U.S. patent application Ser. No.17/719,840, filed Apr. 13, 2022, which claims the benefit of priority toU.S. Provisional Application Ser. No. 63/175,907, filed Apr. 16, 2021,which is incorporated by reference herein in its entirety.

TECHNICAL FIELD

This document pertains generally, but not by way of limitation, tosurgical lights.

BACKGROUND

Surgical lights are used in operating rooms to provide light toilluminate a patient and surgical tools in an operating room. Surgicallights can be located on a boom or a stand for positioning over thepatient during a procedure.

SUMMARY

In addition to being directed to surgical lights, the present disclosureincludes systems and methods for improving safety in operating rooms(OR). In particular, the systems and methods described herein mayinclude but are not limited to, minimizing the airflow obstructions thatmay disrupt the OR ventilation airflow that is meant to protect thesterile surgical field.

The sterility of the air of the surgical field in the modern operatingroom (OR) is meant to be protected and maintained by filtered airflowing downward from large vents in the ceiling above the surgicaltable. The theory is that the downward flowing air pushes any airborneparticles and pathogens downward to the floor or out the exhaust ventslocated near the floor.

There are two generally accepted types of OR ventilation: conventionaland laminar flow. Conventional OR ventilation consists of multiple airinlet vents mounted in the ceiling above the surgical table, eachblowing a jet of air toward the surgical table. These jets of air arewell-known to cause massive turbulence in the air of the sterile field.Turbulence both expels air and entrains air, making a clean sweep ofairborne particles from the surgical field air, problematic. Laminarflow ventilation in contrast, flows from the ceiling through vents thatcover the entire area above the surgical table—typically a square thatis 8-9 feet on a side. Laminar flow is defined as air flowing inparallel layers with no disruption between those layers. In other words,there is no turbulence in laminar flow ventilation and thedownward-moving river of highly filtered air can make a clean sweep ofairborne particles from the air over the surgical field.

Laminar flow ventilation has been shown in some studies to be much moreprotective and in other studies to have no advantage over conventionalventilation. One possible explanation for these contradicting results isthat laminar flow is very sensitive to disruption. We have recentlyshown in our laboratory that there are two primary causes of laminarflow disruption in the OR. First is the flow obstruction caused by theequipment such as surgical lights and equipment booms that are typicallyhanging from the ceiling inside the ventilation flow field. Surgicallight “heads” are typically shaped like a horizontal disk that is 30-36inches in diameter. Additionally, the trend in OR design of hanging muchof the equipment from ceiling has introduced relatively massive steelbooms that may be as large as 8 inches wide by 6 inches high, into theair above the sterile surgical field. The most obvious determinant ofthe degree of flow obstruction is the size of the surface areaobstructing the airflow. A 36 inch diameter disk for example, is a verylarge area of obstruction considering that it may be located less than36 inches from the top of the patient on the surgical table.

Next, in engineering terms this disc-shaped light head design would bedescribed as a “flat plate perpendicular to the flow” which results innearly the highest “drag coefficient” of any possible design. The higherthe drag coefficient, the less aerodynamic the design. The relativelyflat surface on the side of the light head facing the airflow (top side)induces significant turbulence as the downward ventilation airflow isforced to part in order to flow around the light head.

The inventors discovered that the relatively flat surface on the side ofthe light head facing away from the downward ventilation airflow (bottomside) is even more important in determining the adverse effect on thesterile field. For example, a 30-36 inch diameter light head preventsthe air flowing around the edges of the light from smoothly recombiningunder the light head, resulting in a broad “wake” of turbulence andvortices that form under the light head. The broad “wake” of turbulenceand vortices that form under the light head actually create a suction—aregion of negative pressure relative to ambient, that can suck airborneparticles into a vortex and keep them airborne for prolonged periods.

The relatively flat surfaces on both the side facing the air flow (topside) and the side facing away from the air flow (bottom side) of thelight heads and booms are the exact opposite of “streamlined”aerodynamic design. The inventors discovered that the massive booms andlights hanging in the laminar flow field cause significant disruption ofthe laminar flow.

The second cause of laminar flow disruption in the OR is even lessobvious—waste heat, especially the approximately 1000 watts of wasteheat from a forced-air patient warming system (FAW). FAW systems work byblowing roughly 40 CFM of heated air into an air blanket positioned onthe patient. The most common FAW blanket covers the chest andoutstretched arms of the patient and the waste heat and air escapes fromthis blanket at the head end of the surgical table. The inventorsdiscovered that the waste heat from an upper body FAW blanketpreferentially forms into convection currents of warm air that risealong the anesthesia side of the vertical “anesthesia screen” drape atthe head end of the surgical table. In this location, the rising warmair is “protected” from the downward ventilation air by theflow-boundary layer “dead zone” that forms next to the verticalanesthesia screen. However, the inventors discovered that even withoutthe “protection” of the anesthesia screen “dead zone,” a convectioncurrent of warm air forms and rises directly into the downwardventilation airflow. At this point, the rising warm air is along theanesthesia side of the anesthesia screen, outside the sterile surgicalfield.

Most ORs have 2-3 surgical lights. The largest light head is typically30-36 inches in diameter and positioned above the head end of thesurgical table, slightly overlapping the vertical anesthesia screendrape. In this location, approximately 25-33% of the light heads' lowersurface is on the anesthesia side of the screen and ˜67-75 of the lightheads' lower surface is on the surgical side of the screen. Theinventors discovered that the turbulence induced by ventilation airflowing past the disk-shaped light head creates a region of relativenegative pressure (vacuum) within a large vortex that forms under thelight head. The large vortex under the light head is much like arotating horizontal cylinder, with its long axis oriented parallel toand adjacent the anesthesia screen. The direction of the rotation isdownward on the side facing the surgical site and upward on the sidefacing the anesthesia screen. The rotation is energized by waste FAWheat passing through the anesthesia screen, warming the air on that sideof the vortex and causing it to rise. The rotation is also energized bythe downward ventilation airflow passing against the side of the vortexfacing the surgical field, causing the vortex to rotate downward on thatside.

The waste FAW heated air rising under or near the edge of the surgicallight along the anesthesia screen gets sucked across the top edge of theanesthesia screen and into the relative vacuum that forms under thelight head. The rising heat that is sucked horizontally into the topside of the vortex immediately under the light, further energizes therotation of the vortex. The turbulent vortex not only prevents theventilation airflow from clearing the air of the sterile surgical field,but it also entrains surgical smoke, airborne particles and pathogens,keeping these contaminates airborne in the sterile field rather thanallowing them to be cleared by the laminar ventilation. Pathogens are arisk to the patient and the surgical smoke is a breathing risk to thesurgical staff.

There is a need for surgical light heads and booms that minimize theobstruction to OR ventilation airflow by applying principles ofaerodynamics to minimize turbulence, vortex formation and low-pressureregion formation in the air of the sterile surgical field.

In some examples, the aerodynamic surgical light heads and booms of thisdisclosure minimize the size of the “blunt body” or “flat plate” surfacearea of both the side facing the OR ventilation airflow and the sidefacing away from the OR ventilation airflow.

In some examples, the light bulbs of this disclosure may be protectivelylocated in one or more substantially tubular light housings that have aninterior width that may be slightly larger than the diameter of an LEDlights' reflector. Multiple light bulbs may be located along the lengthof the substantially tubular light housing. In some examples, the one ormore substantially tubular light housings may be arranged in almost anypattern including but not limited to one or more circles or concentriccircles, one or more squares, a “cross” shape or “H” shape in order toform a light head.

In some examples, the one or more substantially tubular light housingsmay be arranged in two concentric circles, the outer circle might have adiameter of 30-36 inches for example and the inner circle might have adiameter of 12-16 inches for example. This design allows relativelylarge open spaces or “thru-pass ducts” (in contrast to “bypass”) betweenthe concentric substantially tubular light housings, that allowrelatively free airflow directly through the surgical light head. Insome examples, between 33% and 90% of the total projected surface areaof the surgical light head may be open space serving as thru-passducting. Air passing freely through the light head minimizes or evenprevents the wake, turbulence and vacuum from forming on the lower sideof the light.

In some examples, it may be aerodynamically advantageous for thesubstantially tubular light housings to be a vertically elongated shapein cross section. In some examples, the vertically elongated shape ofthe substantially tubular light housings in cross section, may include asubstantially semi-circular lower section and a substantially parabolicupper section. Minimizing the width of the one or more substantiallytubular light housings while vertically elongating the shape in crosssection and choosing aerodynamically advantageous curves such as asubstantially parabolic upper section, will minimize the wake,turbulence and vacuum forming on the lower side of the light housings.

In some examples, the walls of the upper section of the one or moresubstantially tubular light housings may be made of moldedfiber-reinforced resin such as carbon fiber or fiberglass. The resultingstructure is very light weight, very strong and rigid. If the upperwalls of the substantially tubular light housings were made of carbonfiber or fiberglass, the resulting light head would not require anyadditional framing for strength. If the upper walls of the substantiallytubular light housings were made of carbon fiber or fiberglass, it wouldbe very easy to mold complex aerodynamic shapes. In some examples, thesurgical light heads of this disclosure may weigh less than 20 lbs. Incontrast, prior art light heads typically weigh ˜100 lbs.

In some examples, the individual LED lights within the substantiallytubular light housings are each mounted in their own cone-shapedreflector. In some examples, the walls of the lower section of the oneor more substantially tubular light housings may be made of a clearplastic to cover the open lower side and protect the light bulbs insidewhile letting the lights shine downward. In some examples, the clearplastic lower section may be molded into a semi-circular shape incross-section to avoid distortion of the light beams while maintainingan aerodynamically advantageous shape. The use of LED lights may beadvantageous because they produce minimal heat and their color outputcan be adjusted.

In some examples, the substantially tubular light housings might be inthe form of a circle that creates the outer perimeter of the surgicallight head. Multiple light bulbs may be mounted at intervals around theentire circular length of the substantially tubular light housing.

In some examples, the surgical light of this disclosure eliminates thelaterally attached boom arm(s) and pivot joints of the prior art lightsby moving the distal boom arm joint to the geographical center of thelight head. In some examples, a ball and socket type of joint may belocated at the “geographical center” and “center of mass” of the lighthead which would be the center of a circular light head or the crossingpoint of a cross-shaped light head for example. In order for a surgicallight head to be repositioned easily and stay in the position that it isput by the operator, the boom joint at the light head must be lined updirectly with the center of mass or center of gravity of the light head.In some examples, the perfectly balanced center of gravity in all planeseliminates torque on the light head and allows a light head constructionthat does not require internal metal framing. In some examples, a shortdistal boom arm accesses the light head in the center of the upper side,eliminating the added weight, complexity and airflow obstructions of theside-mounted prior art surgical lights.

In some examples, these same aerodynamic principles may advantageouslybe applied to boom design as well. Even a massive steel boom arm thatmay be as large as 8 inches wide by 6 inches high could be replaced byone or more aerodynamically shaped boom arms. In some examples, thevertical dimension of an aerodynamic boom arm should be at least 2 timesthe horizontal dimension. The majority of the lifting strength isafforded by the vertical side walls of the square or rectangular tubing.Therefore, eliminating most of the steel in the width has little effecton the lifting strength of the boom arm. However, it significantlyreduces the “blunt body” or “flat plate” surface area of both the sidefacing the OR ventilation airflow and the side facing away from the ORventilation airflow. This change alone would greatly reduce the wake,turbulence and vacuum forming on the lower side of the boom arms.

In some examples, the cross-sectional shape of an aerodynamically shapedboom arm may have a substantially parabolic-shaped upper section and asubstantially parabolic-shaped lower section. In some examples, the boomarms may be made of aluminum that has been extruded in the chosenaerodynamic shape and size.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings, which are not necessarily drawn to scale, like numeralsmay describe similar components in different views. Like numerals havingdifferent letter suffixes may represent different instances of similarcomponents. The drawings illustrate generally, by way of example, butnot by way of limitation, various examples discussed in the presentdocument. Any combination of the features shown and described in thisdisclosure, including combinations of fewer or more features is withinthe content of this disclosure. Modules, systems and methods includingindividual features described herein, without combinations of featuresas shown in the examples (for the sake of brevity), are also within thescope of this disclosure.

FIG. 1 shows a perspective view of an illustrative prior art surgicallight, in accordance with at least one example.

FIG. 2 shows a perspective view of an illustrative prior art surgicallight, in accordance with at least one example.

FIG. 3 shows a side view of an illustrative prior art surgical light andair currents flowing around it, in accordance with at least one example.

FIG. 4 shows a vertical cross-sectional view of an illustrative lighthousing, in accordance with at least one example.

FIG. 5 shows a vertical cross-sectional view of an illustrative lighthousing, in accordance with at least one example.

FIG. 6 shows a horizontal cross-sectional view of an illustrative lighthead, in accordance with at least one example.

FIG. 7 shows a horizontal cross-sectional view of an illustrative lighthead, in accordance with at least one example.

FIG. 8 shows a longitudinal cross-sectional view of an illustrativelight housing, in accordance with at least one example. Thecross-section view direction corresponds to a cross-section taken alongthe direction of line 8-8 in FIG. 4 .

FIG. 9 shows a perspective view of an illustrative light head, inaccordance with at least one example.

FIG. 10 shows a vertical cross-sectional view of an illustrativeaerodynamic articulating boom arm, in accordance with at least oneexample.

FIG. 11 shows a vertical cross-sectional view of an illustrativeaerodynamic extension boom arm, in accordance with at least one example.

FIG. 12 shows cross-sectional view of an illustrative light systemhaving a ball and socket type joint, in accordance with at least oneexample. The cross-section view corresponds to a cross-section takenalong the direction of line 8-8 in FIG. 4 .

DETAILED DESCRIPTION

The following detailed description is exemplary in nature and is notintended to limit the scope, applicability, or configuration of theinvention in any way. Rather, the following description providespractical illustrations for implementing exemplary examples of thepresent invention. Examples of constructions, materials, dimensions, andmanufacturing processes are provided for selected elements, and allother elements employ that which is known to those of skill in the fieldof the invention. Those skilled in the art will recognize that many ofthe examples provided have suitable alternatives that can be utilized.

As described herein, operably coupled can include, but is not limitedto, any suitable coupling, such as a fluid (e.g., liquid, gas) coupling,an electrical coupling or a mechanical coupling that enables elementsdescribed herein to be coupled to each other and/or to operate togetherwith one another (e.g., function together).

Directional indicators may be used with their normal customary meaningunder typical orientation of function during surgery. For example, uppercan reference a direction generally upward. For example, but not limitedto, facing towards a ceiling during normal surgical use or the portionlocated above and facing away from a patient during normal surgical use.Likewise, lower can reference a direction generally below or facing awayfrom a corresponding upper portion. For example, but not limited to,facing generally towards a floor or patient during normal surgical useor the portion facing towards the floor or patient during normal use.Example coordinates showing various directional indicators are providedthroughout this disclosure, In some example, these directionalindicators indicate directions, though in some instances, they canspecifically describe an axis. For example, in prior art FIG. 1 ,directional indicators V, L1 and L2 describe a vertical or heightdirectional indicator V, a lateral or width directional indicator L1,and a longitudinal or width directional indicator L2. Such a coordinatesystem can be used with various surgical light systems described herein.

Examples of prior art surgical lights are shown in FIGS. 1,2 and 3 ,which are described together. Traditional surgical light head 2 designshouse the light bulbs in large disc-shaped enclosures that may be 30-36inches in diameter D and 4-12 inches thick T. Traditional surgical lightheads 2 are substantially flat on their lower surface 4 and the uppersurface 6 may be flat or slightly rounded. Prior art surgical lightshave been made in many other shapes including squares, “H” shapes andmultiple circles. All have a substantially flat lower surface 4 and asubstantially flat or slightly rounded upper surface 6 in common.

Surgical lights are typically mounted to the ceiling of the OR through aseries of boom arms and articulating joints. Extension arm 10 wouldtypically be mounted to the pedestal (not shown) that is attached to theceiling (not shown). Extension arm 10 typically attaches to articulatingarm 12 through the extension/articulating joint 16. Articulating arm 12typically attaches to yoke 14 through the arm/yoke joint 18. Yoke 14typically attaches to the light head 2 through the yoke/light head joint20. The yoke 14 may be single armed as shown in FIG. 1 or double armedas shown in FIG. 2 . The various arms and joints of the boom system aredesigned to allow full movement of the light and to keep the light inthe position that it is placed.

As shown in FIG. 3 , in engineering terms this disc-shaped light head 2design would be described as a “flat plate perpendicular to the flow”which results in nearly the highest “drag coefficient” of any possibledesign. The higher the drag coefficient, the less aerodynamic thedesign. The relatively flat upper surface 6 on the side of the lighthead 2 facing the laminar airflow 22 induces significant turbulence 24as the downward ventilation airflow is forced to part in order to flowaround the light head 2.

The relatively flat lower surface 4 on the side of the light head 2facing away from the downward ventilation airflow (e.g., 22) is evenmore important in determining the adverse effect on the sterile field. A30-36 inch diameter D light head prevents the air flowing around theedges of the light head 2 from smoothly recombining under the light head2, resulting in a broad “wake” of turbulence and vortices 26 that formunder the light head. The broad “wake” of turbulence and vortices 26that form under the light head 2 actually create a suction—a region ofnegative pressure 28 relative to ambient, that can suck in airborneparticles and keep them airborne for prolonged periods. This suction issimilar to the suction that forms behind a semi-trailer on the highway.The air rushing past the flat back of the trailer produces tremendousvortices and a zone of negative pressure or partial vacuum immediatelybehind the trailer.

In some examples, the aerodynamic surgical light heads and booms of thisdisclosure minimize the size of the “blunt body” or “flat plate” surfacearea of both the side facing the OR ventilation airflow (e.g., uppersurface 6) and the side facing away from the OR ventilation airflow(e.g., lower surface 4). In some examples as shown in a perspective viewin FIG. 9 , the surgical light head 92 of this disclosure minimizes thecross sectional area of the light housings 930A,B in order to minimizedisturbances to the downward flowing OR ventilation. Open spaces orthru-pass ducts 940A-F in the light head 92 allow ventilation air topass freely through the light head 92 in order to prevent the formationof a broad “wake” of turbulence, vortices and negative pressure fromforming under the light head 92.

In some examples as shown in cross-section in FIG. 4 , the light sourcesuch as LEDs or bulbs 432 of this disclosure may be protectively locatedin one or more substantially tubular light housings 430 that have aninterior width that is slightly larger than the diameter of an LEDlights' reflector 434. For example, if the diameter of the reflector 434for a 2,000-3,000 lumen LED bulb 432 is 1.0 inch, the interior width W1of the light housing 430 may be as little as 1.25 inches and theexterior width W2 of the light housing 430 may be as little as 1.5inches. While minimizing the width of the light housings 430 may beadvantageous, wider light housings 430 are also anticipated. In someexamples the lower section 436 is made of a molded clear plastic thatallows the light beam from LED 432 to shine out of the light housing430. Suitable clear plastics include but are not limited topolycarbonate, acrylic and PVC.

In some examples, the one or more substantially tubular light housings430 may be substantially circular in cross section. In some examples asshown in FIG. 4 , the inventors have discovered that it may beaerodynamically advantageous for the substantially tubular lighthousings 430 to be a vertically elongated shape in cross-section suchthat the vertical dimension V1 is at least 1.5 times greater than thehorizontal width H1. In some examples, the vertically elongated shape ofthe substantially tubular light housings 430 in cross section, mayinclude a substantially semi-circular lower section 436 and asubstantially parabolic upper section 438. In some examples as shown inFIG. 5 , the vertically elongated shape of the substantially tubularlight housings 530 in cross section, may include a curved lower section536 and a substantially pointed upper section 538 much like a tear drop.Other combinations of elongate, streamlined aerodynamic shapes areanticipated. Minimizing the width, such as the maximum width W1, of theone or more substantially tubular light housings 430,530 whilevertically elongating the shape in cross-section and choosingaerodynamically advantageous curves such as a substantially parabolicupper section 438, will minimize the wake, turbulence and vacuum formingon the lower side of the light housings 430,530.

As shown in horizontal cross-section in FIG. 6 , multiple light bulbs632 and reflectors 634 may be located along the length of thesubstantially tubular light housing 630A,B. In some examples, the one ormore substantially tubular light housings 630A,B may be arranged in twoconcentric circles, the outer circle might have a diameter D1 of 30-36inches for example and the inner circle might have a diameter D2 of12-16 inches for example. This design allows relatively large openspaces or “thru-pass ducts” 640A-D between the concentric light housings630A,B, that allow relatively free airflow directly through the surgicallight head 62 (in contrast to “bypass ducts” that would direct the flowaround the light head 62). In this example, if the light housings 630A,Bwere 1.5 inch in width, approximately 80% of the total projected surfacearea (e.g., within the outer perimeter 642) of the surgical light head62 may be open space serving as thru-pass ducting 640A-D. In someexamples, between 25% and 90% of the total projected surface area of thesurgical light head 62 may be open space serving as thru-pass ducting640A-D.

In the case of surgical lights, it is not feasible to simply make thetotal surface area of the light head smaller because the individuallight bulbs must be spread out over a relatively large area in order tominimize shadow formation from the surgeon's head. Therefore, as shownin FIG. 6 , in order to allow the lights to be spread out and yetminimize “blunt body” or “flat plate” surface area creating wake,turbulence and vacuums, large areas of open space or thru-pass ducts640A-D are placed between the substantially tubular light housings630A,B. Air passing freely through the light head 62 minimizes or evenprevents the wake, turbulence and vacuum from forming on the lower sideof the light head 62.

In some examples, the one or more substantially tubular light housings630A,B may be arranged in almost any pattern including but not limitedto one or more: circles or concentric circles, squares, hexagons,“cross” shapes, “H” shapes or any other geometric shape in order to forma light head. For example as shown in FIG. 7 , the light head 72 may bein a substantially “cross” shape. In this example, the thru-pass ducts740A-C also include open spaces 740D,E. To calculate the percentage“surface” area represented by the thru-pass ducts, a perimeter 742 canbe drawn around the tips of the light housings 730 and a total “surface”area 744 calculated. In the case of the circular light head 62 in FIG. 6, the perimeter 642 can be the outer dimension of the outer lighthousing 630A. The light head 72 can include lights 732, surrounded byreflectors 734

In some examples, the walls of the upper section 438,538 of the one ormore substantially tubular light housings 430,530 may be made of moldedfiber-reinforced resin such as carbon fiber or fiberglass. The resultingstructure is very light weight, very strong and rigid. Polyester resinand other moldable resins are also anticipated. In some examples, theupper walls 438,538 of the substantially tubular light housings 430,530are made of carbon fiber or fiberglass so that the resulting light head62,72 does not require any additional framing for strength. Eliminatingframing also eliminates some weight and complexity. In some examples,the upper walls 438,538 of the substantially tubular light housings430,530 are made of carbon fiber or fiberglass so that complexaerodynamic shapes can be easily molded. In some examples, the upperwalls 438,538 of the substantially tubular light housings 430,530 can bemade of carbon fiber or fiberglass so that the outer surface of coloredresin “gel coat” is more durable than paint and does not chip and fallinto the sterile field if two lights bump into each other, as has beenreported with painted steel lights and booms.

Other materials and constructions for the walls of the upper section438,538 of the one or more substantially tubular light housings 430,530are anticipated. For example, 3-D printing or “additive manufacturing”may be ideal for the complex design. Pressed metal such as aluminum canalso be used. Combinations of materials may be advantageous. Forexample, an outer shell surface 538A may be 3-D printed and an innerlayer 538B of fiber reinforced resin may be advantageously applied toprovide added strength. Conversely, the outer shell 538 may be made ofmolded fiber reinforced resin and the interior partitions and fixturesmay be 3-D printed.

In some examples, the walls of the lower section 436,536 of the one ormore substantially tubular light housings 430,530 may be made of a clearplastic to cover the open lower side and protect the LED bulbs 432,532inside, while allowing the lights shine downward. In some examples, theclear plastic lower section 436,536 may be molded into a semi-circularshape in cross-section as shown in FIGS. 4 and 5 , to avoid distortionof the light beams while maintaining an aerodynamically advantageousshape. Substantially flat lenses (e.g., 436, 536) covering the reflector434,534 are also anticipated.

In some examples as shown in the vertical longitudinal section of FIG. 8(e.g., a cross-sectional direction corresponding to a cross-sectiontaken along line 8-8 in FIG. 4 ), the individual LED lights 832A,Bwithin the substantially tubular light housing 830 may each be mountedin their own substantially cone-shaped reflector 834A,B. Reflectors witha generally parabolic shape and LED bulbs that do not require reflectorsare also anticipated. In some examples, two small plastic or metal axils846A-C are attached to opposite sides of the reflector 834A,B near tothe open side of the reflector and project radially outward in thelongitudinal axis of the substantially tubular light housing 830. Thelight axils 846A-C may be seated into bushings 848A,B on each side ofthe reflector 834A,B in the light housing 830 that orient the lightaxils 846A-C substantially parallel to the long axis of thesubstantially tubular light housing 830, allowing each light bulb 832A,Band its attached reflector 834A,B to pivot perpendicularly to the longaxis of the substantially tubular light housing 830. Pivoting the lights832A,B may be beneficial to refocus the multiple lights 832A,B as thedepth of field changes due to the operators' repositioning the surgicallight head 62,72 at different distances from the surgical site.

In some examples as shown in FIG. 6 , the substantially tubular lighthousings 630A,B might be in the form of a circle that creates the outerperimeter 642 of the surgical light head 62. Multiple light bulbs 634may be mounted proximate each other around substantially the entirecircular length of the substantially tubular light housing 630A,B. Insome examples, adjacent concentric circular substantially tubular lighthousings 630A,B may be connected together through spokes 676A-D in a“wheel and spoke” design. In some examples, spokes 676A-D may projectinward to attach to the socket 658 at the geographic center of the lighthead 62. Spoke designs can be incorporated into other examples, such asthe spokes 776 of FIG. 7

In some examples as shown in FIG. 8 , the light axils 846A,B are seatedinto bushings 848A,B on each side of the reflectors 834A,B and thebushings 848A,B may be mounted on cross members 850A,B. In someexamples, cross members 850A,B are reinforcing partitions that arebonded to the inner wall 830A of the substantially tubular light housing830 creating a honeycomb-like structure to provide mechanical strengthand stiffness to the substantially tubular light housing 830. The crossmembers 850A,B may be made of plastic or metal and may be bonded to thewalls of the light housing 830 with any suitable adhesive or resin.

In some examples, the adjacent axils 846A,B of adjacent lights 832A,Bmay be mechanically linked together through a flexible linkage 852.Linking adjacent lights 832A,B together allows the pivoting of one light832A to cause an equal pivoting of the adjacent light 832B which causesthe next light to pivot and so on around the whole circular length.Flexible linkages 852 include but are not limited to cables (not shown),ball-shaped Allen wrench heads 854 and sockets 856, “U joints” (notshown) or “lock and key” connectors (not shown) of various shapes.

Traditionally, surgical lights such as shown in FIG. 1 , are focused byturning light handle 8. Turning light handle 8 pivots the individuallights inward or outward in order to keep the total light beam focusedon the surgical site. As the light head 2 gets closer to the surgicalfield, the lights have to be directed more and more inward. Theindividual lights 432,532,632,732,832 of this disclosure can be easilyrotated inward or outward in a coordinated fashion by linking arotational movement of the light handle (e.g., 8; FIG. 1 ) to the linkedchain of individual lights 432,532,632,732,832 through one or morelinkages.

In order for a surgical light head to be repositioned easily and stay inthe position that it is put by the operator, the boom joint at the lighthead must be lined up directly with the center of mass or center ofgravity of the light head. As shown in FIGS. 1 and 2 , the center ofmass of prior art light heads 6 is inside the disk-shaped light head 2.In other words, the point at which the light head is balanced in anyattitude (rotating up, down or sideways), is inside the volume of thelight head 2 and therefore not accessible for a pivot joint. As aresult, prior art disk-shaped light heads, are attached on their outsideperimeter to the boom through either a single arm at 90° (as shown inFIG. 1 ) or a double armed “yoke” that is attached at both 90° and 270°(as shown in FIG. 2 ). If the disk-shaped light head is 6 inches thickfor example, the center of mass will be approximately at the midpoint,about 3 inches from the light face. Pivoting at this location willprevent the light from naturally pitching forward or backward as itsvertical angle is changed.

Further as shown in prior art FIGS. 1 and 2 , side attachment pivotjoints 20 to the light head 2 allow for a smooth vertical movement ofthe light head 2. However, this design requires a second pivot point,usually located at the arm/yoke joint 18 to allow side to sideadjustments. As a result, these side attachment pivot joints result inseveral negative consequences. The distal boom arm or arms add weight,complexity and airflow obstructions. Attaching a single arm to one sideof the light head creates a lever that applies considerable torque tothe boom arm, the joint and the light head. This is especially importantsince the average prior art light head 2 weighs approximately 100 lbs.,which is a lot of weight to support out at the end of multiple boomarms. One result is the need for an internal metal frame in the lighthead to handle the torque and support the weight. Metal frames take upspace and add weight. In some examples, the light-weight light heads62,72 of this disclosure do not require metal frames and weigh less than20 lbs. Lighter weight light heads of this disclosure allows all of thesupport booms and arms to be lighter and also allows for easierrepositioning of the surgical light by the operator.

In some examples as shown in FIGS. 6 and 7 , the surgical light of thisdisclosure eliminates the laterally attached boom arm(s) and pivotjoints of the prior art lights by moving the distal boom arm joint tothe geographical center and center of mass of the light head 62,72. Insome examples, a ball and socket type of joint 662,762 may be located atthe geographical center of the light head 62,72 which would be thecenter of a circular light head 62 or the crossing point of across-shaped light head 72 for example. Since a ball and socket joint662,762 can pivot both vertically and horizontally, one of the twosingle direction joints and boom arms of the prior art lights can beeliminated saving weight, complexity, cost and airflow disruption.

In some examples as shown in FIGS. 6 and 7 , a ball and socket type ofjoint 662,762 may be located at the geographical center of the lighthead 62,72. In some examples as shown in FIG. 12 a ball and socket typeof joint 1262 may be located approximately midway between the uppermostand lowermost sides of the substantially tubular light housings 1230A,Bin order to position the ball 1260 and socket 1258 of the joint 1262 atthe exact center of mass (center of gravity) of the light head. In someexamples, thru-pass ducts 640E,740B,1240 are located at the geographiccenter of the light head 62,72,122 in order to allow the ball and socketjoint 662,762,1262 to be located within the volume of the light head62,72,122 at the center of mass. In some examples, the substantiallytubular light housings 630,730,1230AB may be connected to the centrallylocated socket 1258 or ball 1260 of the joint 1262 by spokes 1276A,B.

Pivoting on a ball and socket joint located at the center of massresults in easy adjustment and the light head naturally stays in anyposition that it is put into by the operator, because it is in balancein all attitudes. Naturally staying in position advantageouslyeliminates the need for braking systems that add weight, complexity andresistance to movement. In some examples, positioning the ball andsocket joint 662,762,1262 within the volume of the light head 62,72,122at the center of mass, perfectly balances the center of gravity in allplanes and eliminates torque on the light head, allowing a light headconstruction that does not require internal metal framing for strength.

In some examples as shown in FIGS. 9 and 12 , a short distal boom arm964,1264 accesses the light head 92,122 in the center of the upper side,eliminating the added weight, complexity and airflow obstructions of theside-mounted prior art surgical lights (e.g., FIGS. 1-3 ). In someexamples, the socket 658,758,1258 is structurally connected to the lighthead 62,72,122 and the ball 660,760,1260 is structurally connected tothe distal arm 964,1264 of the boom system although the reverse isanticipated. In some examples, the short distal boom arm 964,1264 ofthis disclosure, eliminates the need for the prior art yoke 14, thearm/yoke joint 18 and the yoke/light head joint 20 shown in FIGS. 1 and2 . In some examples, as shown in FIGS. 9 and 12 , the light handle128,928 may be attached at the geographic center of the light head 92,122.

In some examples, these same aerodynamic principles may advantageouslybe applied to boom design as well. Typically, prior art boom arms aremade of square or rectangular steel tubing. The “extension arm” which isthe most proximal boom arm attached to the ceiling pedestal mount, notonly supports the most weight but also can experience massive torsionalforces if the “articulating arm” is perpendicular to the extension arm.The prior art extension arm of some boom systems may be as large as 8inches wide and 6 inches high. The articulating arms tend to be muchsmaller in cross section because they support less weight and do notexperience the same torsional forces. Articulating arms may be 2 inchessquare or circular. Clearly the “blunt body” or “flat plate” surfacearea of an 8 inch-wide extension arm is significant and will produce abroad “wake” of turbulence and vortices under the boom arm.

In some examples as shown in cross-section in FIG. 10 , anaerodynamically shaped boom arm for an articulating arm might be 1 inchwide and 3 inches high for example. In some examples, the verticaldimension of a boom arm should be at least 2 times the horizontaldimension. In this example, a 1 inch wide by 3 inch tall shape will befar more aerodynamic. Other dimensions are anticipated.

Replacing the prior art extension arms of some boom systems that may beas large as 8 inches wide and 6 inches high with aerodynamic arms ismore challenging because extension arms must also tolerate torsionalforces. In some examples as shown in cross-section in FIG. 11 , anaerodynamically shaped extension boom arm 1168 might for example be madeof two parallel 1.5 inch wide and 4 inches high articulating boom arms1166A,B (other dimensions are anticipated). The two parallelarticulating boom arms 1166A,B may be joined together with one or morereinforcing struts 1170, to form a beam structure with added torsionalstrength. The open spaces between the parallel booms 1166A,B and thereinforcing struts 1170 allow free airflow between the parallel booms1166A,B. In some examples, the space between the two aerodynamicallyshaped parallel boom arms 1166A,B serves the same purpose as thethru-pass ducts 640,740 described above for the surgical lights.

In some examples as shown in FIG. 10 , the cross-sectional shape of anaerodynamically shaped articulating boom arm 1066 may have asubstantially parabolic-shaped upper section 1072 and a substantiallyparabolic-shaped lower section 1074. In some examples, thecross-sectional shape of an aerodynamically shaped boom arm may have asubstantially pointed-shaped upper section and a substantiallypointed-shaped lower section. In some examples, the cross-sectionalshape of an aerodynamically shaped boom arm may have a substantiallysemicircular-shaped upper section and a substantiallysemicircular-shaped lower section. In some examples, the cross-sectionalshape of an aerodynamically shaped boom arm may be any combination ofthese shapes or other suitable aerodynamic shapes.

In some examples, the boom arms may be made of aluminum that has beenextruded in the chosen aerodynamic shape and size. The superior strengthof the boom arms 1066,1166 shown in FIGS. 10 and 11 is due to theircross-sectional shape, which means that they can be made of aluminuminstead of prior art steel. In some examples, it may be desirable tomake the boom arms 1066,1166 of this disclosure out of aluminum insteadof the prior art steel, in order to make the entire boom system muchlighter. Further, aluminum can be used to extrude complex shapes such asthe boom cross section shown in FIG. 10 .

Reducing the width W3 versus the height H3 of the boom arms of thisdisclosure compared to prior art boom arms and making theircross-sectional shape vertically elongate and adding aerodynamic curvesto the upper and lower surfaces will significantly reduce the “bluntbody” or “flat plate” surface area of both the side facing the ORventilation airflow and the side facing away from the OR ventilationairflow. The boom arms of this disclosure would greatly reduce the wake,turbulence and vacuum forming on the lower side of the boom arms. Themuch lighter light head 92 of this disclosure allows lighter weightaluminum boom arms 1066,1166, both of which will drastically reduce theover-all weight of this boom system and lights compared to prior artsurgical light boom systems. The reduced weight of the boom arm andsurgical light system may allow installation onto operating roomceilings without requiring the massive superstructure currently neededto support prior art boom systems. This vastly reduces the complexityand cost of the boom and surgical light systems of this disclosure.

The above detailed description includes references to the accompanyingdrawings, which form a part of the detailed description. The drawingsshow, by way of illustration, specific embodiments in which theinvention can be practiced. These embodiments are also referred toherein as “examples.” Such examples can include elements in addition tothose shown or described. However, the present inventors alsocontemplate examples in which only those elements shown or described areprovided. Moreover, the present inventors also contemplate examplesusing any combination or permutation of those elements shown ordescribed (or one or more aspects thereof), either with respect to aparticular example (or one or more aspects thereof), or with respect toother examples (or one or more aspects thereof) shown or describedherein.

In this document, the terms “a” or “an” are used, as is common in patentdocuments, to include one or more than one, independent of any otherinstances or usages of “at least one” or “one or more.” In thisdocument, the term “or” is used to refer to a nonexclusive or, such that“A or B” includes “A but not B,” “B but not A,” and “A and B,” unlessotherwise indicated. In this document, the terms “including” and “inwhich” are used as the plain-English equivalents of the respective terms“comprising” and “wherein.” Also, in the following claims, the terms“including” and “comprising” are open-ended, that is, a system, device,article, composition, formulation, or process that includes elements inaddition to those listed after such a term in a claim are still deemedto fall within the scope of that claim. Moreover, in the followingclaims, the terms “first,” “second,” and “third,” etc. are used merelyas labels, and are not intended to impose numerical requirements ontheir objects. The terms approximately, about or substantially can bedefined as being within 10% of the stated value or arrangement.

The above description is intended to be illustrative, and notrestrictive. For example, the above-described examples (or one or moreaspects thereof) may be used in combination with each other. Otherexamples can be used, such as by one of ordinary skill in the art uponreviewing the above description. The Abstract is provided to allow thereader to quickly ascertain the nature of the technical disclosure. Itis submitted with the understanding that it will not be used tointerpret or limit the scope or meaning of the claims. Also, in theabove Detailed Description, various features may be grouped together tostreamline the disclosure. This should not be interpreted as intendingthat an unclaimed disclosed feature is essential to any claim. Rather,inventive subject matter may lie in less than all features of aparticular disclosed example. Thus, the following claims are herebyincorporated into the Detailed Description as examples or examples, witheach claim standing on its own as a separate example, and it iscontemplated that such examples can be combined with each other invarious combinations or permutations. The scope of the invention shouldbe determined with reference to the appended claims, along with the fullscope of equivalents to which such claims are entitled.

NOTES AND VARIOUS EXAMPLES

Example 1 is an aerodynamic surgical light, the aerodynamic surgicallight comprising: a light head made of one or more substantially tubularlight housings; and the substantially tubular light housings contain andprotect a plurality of LED lights and their respective reflectors thataim a light beam toward the lower side of the substantially tubularlight housings; and the substantially tubular light housings arevertically elongate with a vertical dimension at least 1.5 times greaterthan the horizontal width; and the vertically elongated substantiallytubular light housings include upper sections that are aerodynamicallycurved or pointed to streamline airflow past the light housings; and theaerodynamic curves include but are not limited to: substantiallyparabolic shapes, substantially pointed shapes, substantiallysemicircular shapes and combinations thereof; and the upper sections ofthe substantially tubular light housings are made of molded plasticresin reinforced with carbon fibers or glass fibers; and the lowersections of the substantially tubular light housings are made of a clearmoldable plastic; and the one or more substantially tubular lighthousings are connected together to form a geographic center of masswhere the substantially tubular light housings connect to a ball andsocket joint that connects the light housings to a supporting boomsystem.

In Example 2, the subject matter of Example 1 includes, wherein the oneor more substantially tubular light housings are formed into one or moreconcentric substantially circular tubes with open spaces between the oneor more concentric substantially circular tubes.

In Example 3, the subject matter of Example 2 includes, wherein the openspaces comprise greater than 40% of the projected surface area of thesurgical light.

In Example 4, the subject matter of Examples 2-3 includes, wherein theone or more concentric substantially circular tubes with open spacesbetween the one or more concentric substantially circular tubes areconnected together by spokes forming a “wheel and spoke” structure.

In Example 5, the subject matter of Example 4 includes, wherein the balland socket joint and a light handle are connected to the center of thewheel and spoke structure.

In Example 6, the subject matter of Examples 1-5 includes, wherein theplurality of LED lights and their respective reflectors in the one ormore concentric substantially circular tubes are each mounted on axilsthat allow the reflector and light to pivot from a first positionshining straight downward collectively creating a cylinder of light to asecond position shining inward collectively creating a cone of light.

In Example 7, the subject matter of Example 6 includes, wherein theadjacent axils of the adjacent lights are coupled to each other throughflexible couplings allowing the positioning of one or more lights todictate the position of all of the lights in each substantially circulartube.

In Example 8, the subject matter of Example 7 includes, wherein theflexible couplings include but are not limited to: cables, ball-shapedAllen wrench heads and sockets, “U joints” or “lock and key” connectorsof various shapes.

In Example 9, the subject matter of Examples 1-8 includes, wherein thewidth of the substantially tubular light housings is less than threetimes the diameter of the LED reflectors.

Example 10 is an aerodynamic surgical light, the aerodynamic surgicallight comprising: a light head made of one or more substantially tubularlight housings; and the substantially tubular light housings contain andprotect a plurality of LED lights and their respective reflectors thataim a light beam toward the lower side of the substantially tubularlight housings; and the substantially tubular light housings arevertically elongate with a vertical dimension at least 1.5 times greaterthan the horizontal width; and the vertically elongated substantiallytubular light housings include upper sections that are aerodynamicallycurved or pointed to streamline airflow past the light housings; and theaerodynamic curves include but are not limited to: substantiallyparabolic shapes, substantially pointed shapes, substantiallysemicircular shapes and combinations thereof; and the upper sections ofthe substantially tubular light housings are made of molded plasticresin reinforced with carbon fibers or glass fibers; and the lowersections of the substantially tubular light housings are made of a clearmoldable plastic; and the one or more substantially tubular lighthousings are formed into one or more concentric substantially circulartubes with open spaces between the one or more concentric substantiallycircular tubes; and wherein the open spaces comprise greater than 40% ofthe projected surface area of the surgical light.

In Example 11, the subject matter of Example 10 includes, wherein theone or more concentric substantially circular tubes with open spacesbetween the one or more concentric substantially circular tubes areconnected together by spokes forming a “wheel and spoke” structure.

In Example 12, the subject matter of Example 11 includes, wherein theone or more substantially tubular light housings are connected togetherto form a geographic center of mass where the substantially tubularlight housings connect to a ball and socket joint that connects thelight housings to a supporting boom system.

In Example 13, the subject matter of Example 12 includes, wherein theball and socket joint and a light handle are connected to the center ofthe wheel and spoke structure.

In Example 14, the subject matter of Examples 10-13 includes, whereinthe plurality of LED lights and their respective reflectors in the oneor more concentric substantially circular tubes are each mounted onaxils that allow the reflector and light to pivot from a first positionshining straight downward collectively creating a cylinder of light to asecond position shining inward collectively creating a cone of light.

In Example 15, the subject matter of Example 14 includes, wherein theadjacent axils of the adjacent lights are coupled to each other throughflexible couplings allowing the positioning of one or more lights todictate the position of all of the lights in each substantially circulartube.

In Example 16, the subject matter of Example 15 includes, wherein theflexible couplings include but are not limited to: cables, ball-shapedAllen wrench heads and sockets, “U joints” or “lock and key” connectorsof various shapes.

In Example 17, the subject matter of Examples 10-16 includes, whereinthe width of the substantially tubular light housings is less than threetimes the diameter of the LED reflectors.

Example 18 is an aerodynamic surgical light, the aerodynamic surgicallight comprising: a light head made of one or more substantially tubularlight housings; and the substantially tubular light housings contain andprotect a plurality of LED lights and their respective reflectors thataim a light beam toward the lower side of the substantially tubularlight housings; and the substantially tubular light housings arevertically elongate with a vertical dimension at least 1.5 times thehorizontal width; and the vertically elongated substantially tubularlight housings include upper sections that are aerodynamically curved orpointed to streamline airflow past the light housings; and theaerodynamic curves include but are not limited to: substantiallyparabolic shapes, substantially pointed shapes, substantiallysemicircular shapes and combinations thereof; and the upper sections ofthe substantially tubular light housings are made of molded plasticresin reinforced with carbon fibers or glass fibers; and the lowersections of the substantially tubular light housings are made of a clearmoldable plastic; and the one or more substantially tubular lighthousings are formed into one or more concentric substantially circulartubes with open spaces between the one or more concentric substantiallycircular tubes; and wherein the one or more concentric substantiallycircular tubes with open spaces between the one or more concentricsubstantially circular tubes are connected together by spokes forming a“wheel and spoke” structure.

In Example 19, the subject matter of Example 18 includes, wherein theopen spaces comprise greater than 40% of the projected surface area ofthe surgical light.

In Example 20, the subject matter of Examples 18-19 includes, whereinthe plurality of LED lights and their respective reflectors in the oneor more concentric substantially circular tubes are each mounted onaxils that allow the reflector and light to pivot from a first positionshining straight downward collectively creating a cylinder of light to asecond position shining inward collectively creating a cone of light.

The aerodynamic surgical light of Example 20, wherein the adjacent axilsof the adjacent lights are coupled to each other through flexiblecouplings allowing the positioning of one or more lights to dictate theposition of all of the lights in each substantially circular tube.

In Example 21 the subject matter of example includes, wherein theflexible couplings include but are not limited to: cables, ball-shapedAllen wrench heads and sockets, “U joints” or “lock and key” connectorsof various shapes.

In Example 22, the subject matter of Examples 18-21 includes, whereinthe one or more substantially tubular light housings are connectedtogether to form a geographic center of mass where the substantiallytubular light housings connect to a ball and socket joint that connectsthe light housings to a supporting boom system.

In Example 23, the subject matter of Example 22 includes, wherein balland socket and a light handle are connected at the center of the wheeland spoke structure.

Example 24 is an aerodynamic surgical light, the aerodynamic surgicallight comprising: a light head made of one or more substantially tubularlight housings; and the substantially tubular light housings contain andprotect a plurality of LED lights and their respective reflectors thataim a light beam toward the lower side of the substantially tubularlight housings; and the width of the substantially tubular lighthousings is less than three times the diameter of the LED reflectors;and the substantially tubular light housings are vertically elongatewith a vertical dimension at least 1.5 times the horizontal width; andthe vertically elongated substantially tubular light housings includeupper sections that are aerodynamically curved or pointed to streamlineairflow past the light housings; and the aerodynamic curves include butare not limited to: substantially parabolic shapes, substantiallypointed shapes, substantially semicircular shapes and combinationsthereof; and the upper sections of the substantially tubular lighthousings are made of molded plastic resin reinforced with carbon fibersor glass fibers; and the lower sections of the substantially tubularlight housings are made of a clear moldable plastic; and the one or moresubstantially tubular light housings are formed into one or moreconcentric substantially circular tubes with open spaces between the oneor more concentric substantially circular tubes; and the plurality ofLED lights and their respective reflectors in the one or more concentricsubstantially circular tubes are each mounted on axils that allow thereflector and light to pivot from a first position shining straightdownward collectively creating a cylinder of light to a second positionshining inward collectively creating a cone of light; and wherein theadjacent axils of the adjacent lights are coupled to each other throughflexible couplings allowing the positioning of one or more lights todictate the position of all of the lights in each substantially circulartube.

In Example 25, wherein the open spaces comprise greater than 40% of theprojected surface area of the surgical light.

In Example 26, the subject matter of Examples 24-25 includes, whereinthe one or more concentric substantially circular tubes with open spacesbetween the one or more concentric substantially circular tubes areconnected together by spokes forming a “wheel and spoke” structure.

In Example 27, the subject matter of Examples 24-26 includes, whereinthe flexible couplings include but are not limited to: cables,ball-shaped Allen wrench heads and sockets, “U joints” or “lock and key”connectors of various shapes.

In Example 28, the subject matter of Examples 24-27 includes, whereinthe one or more substantially tubular light housings are connectedtogether to form a geographic center of mass where the substantiallytubular light housings connect to a ball and socket joint that connectsthe light housings to a supporting boom system.

In Example 29, the subject matter of Examples 24-28 includes, whereinthe width of the substantially tubular light housings is less than threetimes the diameter of the LED reflectors.

Example 30 is at least one machine-readable medium includinginstructions that, when executed by processing circuitry, cause theprocessing circuitry to perform operations to implement of any ofExamples 1-29.

Example 31 is an apparatus comprising means to implement of any ofExamples 1-29.

Example 32 is a system to implement of any of Examples 1-29.

Example 33 is a method to implement of any of Examples 1-29.

1. An aerodynamic surgical light comprising: a light head made of one or more substantially conical light housings; the one or more substantially conical light housings contain a plurality of LED lights and respective reflectors that aim a light beam toward a lower side of the one or more substantially conical light housings; the one or more substantially conical light housings are vertically elongate with a vertical dimension at least 1.2 times greater than a horizontal width; the one or more substantially conical light housings include upper sections that are aerodynamically curved or pointed to streamline airflow past the one or more substantially conical light housings; the aerodynamic curves include at least one of a substantially parabolic shape, a substantially pointed shape, a substantially semicircular shape, and combinations thereof; and the one or more substantially conical light housings are connected together to form a geographic center of mass where the one or more substantially conical light housings connect to a supporting boom system.
 2. The aerodynamic surgical light of claim 1, wherein the one or more substantially conical light housings are formed into one or more concentric substantially circular tubes with open spaces between the one or more concentric substantially circular tubes.
 3. The aerodynamic surgical light of claim 2, wherein the open spaces comprise greater than 30% of the projected surface area of the surgical light.
 4. The aerodynamic surgical light of claim 2, wherein the one or more concentric substantially circular tubes with open spaces between the one or more concentric substantially circular tubes are connected together by spokes forming a wheel and spoke structure.
 5. The aerodynamic surgical light of claim 4, wherein a ball and socket joint and a light handle are connected to the center of the wheel and spoke structure.
 6. The aerodynamic surgical light of claim 1, wherein the plurality of LED lights and their respective reflectors in the one or more concentric substantially circular tubes are each mounted on axils that allow the reflector and light to pivot from a first position shining straight downward collectively creating a cylinder of light to a second position shining inward collectively creating a cone of light.
 7. The aerodynamic surgical light of claim 6, wherein the adjacent axils of the adjacent lights are coupled to each other through flexible couplings allowing the positioning of one or more lights to dictate the position of all of the lights in each substantially circular tube.
 8. The aerodynamic surgical light of claim 7, wherein the flexible couplings include ball-shaped Allen wrench heads and sockets connectors.
 9. The aerodynamic surgical light of claim 1, wherein the upper sections of the one or more substantially conical light housings are made of plastic resin reinforced with carbon fibers or glass fibers and the lower sections of the one or more substantially conical light housings are made of a clear plastic.
 10. An aerodynamic surgical light comprising: a light head made of one or more substantially conical light housings; the one or more substantially conical light housings contain a plurality of LED lights and respective reflectors that aim a light beam toward a lower side of the one or more substantially conical light housings; the one or more substantially conical light housings are vertically elongate with a vertical dimension at least 1.2 times greater than the horizontal width; the one or more substantially conical light housings include upper sections that are aerodynamically curved or pointed to streamline airflow past the light housings; the aerodynamic curves include at least one of substantially parabolic shapes, substantially pointed shapes, substantially semicircular shapes, and combinations thereof; and the one or more substantially conical light housings are formed into one or more concentric substantially circular tubes with open spaces between the one or more concentric substantially circular tubes, wherein the open spaces comprise greater than 30% of the projected surface area of the surgical light.
 11. The aerodynamic surgical light of claim 10, wherein the one or more concentric substantially circular tubes with open spaces between the one or more concentric substantially circular tubes are connected together by spokes forming a wheel and spoke structure.
 12. The aerodynamic surgical light of claim 11, wherein the one or more substantially conical light housings are connected together to form a geographic center of mass where the substantially conical light housings connect to a supporting boom system.
 13. The aerodynamic surgical light of claim 12, wherein a ball and socket joint and a light handle are connected to the center of the wheel and spoke structure.
 14. The aerodynamic surgical light of claim 10, wherein the plurality of LED lights and their respective reflectors in the one or more concentric substantially circular tubes are each mounted on axils that allow the reflector and light to pivot from a first position shining straight downward collectively creating a cylinder of light to a second position shining inward collectively creating a cone of light.
 15. The aerodynamic surgical light of claim 14, wherein the adjacent axils of the adjacent lights are coupled to each other through flexible couplings allowing the positioning of one or more lights to dictate the position of all of the lights in each substantially circular tube.
 16. The aerodynamic surgical light of claim 15, wherein the flexible couplings include ball-shaped Allen wrench heads and sockets connectors.
 17. The aerodynamic surgical light of claim 10, wherein the upper sections of the one or more substantially conical light housings are made of plastic resin reinforced with carbon fibers or glass fibers and the lower sections of the one or more substantially conical light housings are made of a clear plastic.
 18. An aerodynamic surgical light comprising: a light head made of one or more substantially conical light housings; the one or more substantially conical light housings contain and protect a plurality of LED lights and respective reflectors that aim a light beam toward the lower side of the substantially conical light housings; the substantially conical light housings are vertically elongate with a vertical dimension at least 1.2 times the horizontal width; the one or more substantially conical light housings include upper sections that are aerodynamically curved or pointed to streamline airflow past the light housings; the aerodynamic curves include at least one of substantially parabolic shapes, substantially pointed shapes, substantially semicircular shapes, and combinations thereof; and the one or more substantially conical light housings are formed into one or more concentric substantially circular tubes with open spaces between the one or more concentric substantially circular tubes, wherein the one or more concentric substantially circular tubes with open spaces between the one or more concentric substantially circular tubes are connected together by spokes forming a wheel and spoke structure.
 19. The aerodynamic surgical light of claim 18, wherein the open spaces comprise greater than 30% of the projected surface area of the surgical light.
 20. The aerodynamic surgical light of claim 18, wherein the plurality of LED lights and their respective reflectors in the one or more concentric substantially circular tubes are each mounted on axils that allow the reflector and light to pivot from a first position shining straight downward collectively creating a cylinder of light to a second position shining inward collectively creating a cone of light.
 21. The aerodynamic surgical light of claim 20, wherein the adjacent axils of the adjacent lights are coupled to each other through flexible couplings allowing the positioning of one or more lights to dictate the position of all of the lights in each substantially circular tube.
 22. The aerodynamic surgical light of claim 18, wherein the upper sections of the one or more substantially conical light housings are made of plastic resin reinforced with carbon fibers or glass fibers and the lower sections of the one or more substantially conical light housings are made of a clear plastic.
 23. The aerodynamic surgical light of claim 18, wherein the one or more substantially conical light housings are connected together to form a geographic center of mass where the substantially conical light housings connect to a supporting boom system.
 24. The aerodynamic surgical light of claim 23, wherein a ball and socket joint and a light handle are connected at the center of the wheel and spoke structure.
 25. An aerodynamic surgical light comprising: a light head made of one or more substantially conical light housings; the one or more substantially conical light housings contain a plurality of LED lights and respective reflectors that aim a light beam toward the lower side of the substantially conical light housings; the one or more substantially conical light housings are vertically elongate with a vertical dimension at least 1.2 times the horizontal width; the one or more substantially conical light housings include upper sections that are aerodynamically curved or pointed to streamline airflow past the light housings; the aerodynamic curves include at least one of substantially parabolic shapes, substantially pointed shapes, substantially semicircular shapes, and combinations thereof; the one or more substantially conical light housings are formed into one or more concentric substantially circular tubes with open spaces between the one or more concentric substantially circular tubes; and the plurality of LED lights and respective reflectors in the one or more concentric substantially circular tubes are each mounted on axils that allow the reflector and light to pivot from a first position shining straight downward collectively creating a cylinder of light to a second position shining inward collectively creating a cone of light, wherein the adjacent axils of the adjacent lights are coupled to each other through flexible couplings allowing the positioning of one or more lights to dictate the position of all of the lights in each substantially circular tube.
 26. The aerodynamic surgical light of claim 25, wherein the open spaces comprise greater than 30% of the projected surface area of the surgical light.
 27. The aerodynamic surgical light of claim 25, wherein the one or more concentric substantially circular tubes with open spaces between the one or more concentric substantially circular tubes are connected together by spokes forming a wheel and spoke structure.
 28. The aerodynamic surgical light of claim 25, wherein the upper sections of the one or more substantially conical light housings are made of plastic resin reinforced with carbon fibers or glass fibers and the lower sections of the one or more substantially conical light housings are made of a clear plastic.
 29. The aerodynamic surgical light of claim 25, wherein the one or more substantially conical light housings are connected together to form a geographic center of mass where the substantially conical light housings connect to a supporting boom system.
 30. The aerodynamic surgical tight of claim 25, wherein the width of the substantially conical light housings is less than three times the diameter of the LED reflectors. 